#    This file is part of Metasm, the Ruby assembly manipulation suite
#    Copyright (C) 2006-2009 Yoann GUILLOT
#
#    Licence is LGPL, see LICENCE in the top-level directory


require 'metasm/cpu/ia32/main'

module Metasm
class Ia32
	# temporarily setup dasm.address_binding so that backtracking
	# stack-related offsets resolve in :frameptr (relative to func start)
	def decompile_makestackvars(dasm, funcstart, blocks)
		oldfuncbd = dasm.address_binding[funcstart]
		dasm.address_binding[funcstart] = { :esp => :frameptr }	# this would suffice, the rest here is just optimisation

		patched_binding = [funcstart]	# list of addresses to cleanup later
		ebp_frame = true

		# pretrace esp and ebp for each function block (cleared later)
		# TODO with more than 1 unknown __stdcall ext func per path, esp -> unknown, which makes very ugly C (*esp-- = 12...); add heuristics ?
		blocks.each { |block|
			blockstart = block.address
			if not dasm.address_binding[blockstart]
				patched_binding << blockstart
				dasm.address_binding[blockstart] = {}
				foo = dasm.backtrace(:esp, blockstart, :snapshot_addr => funcstart)
				if foo.length == 1 and ee = foo.first and ee.kind_of? Expression and (ee == Expression[:frameptr] or
						(ee.lexpr == :frameptr and ee.op == :+ and ee.rexpr.kind_of? ::Integer))
					dasm.address_binding[blockstart][:esp] = ee
				end
				if ebp_frame
					foo = dasm.backtrace(:ebp, blockstart, :snapshot_addr => funcstart)
					if foo.length == 1 and ee = foo.first and ee.kind_of? Expression and (ee == Expression[:frameptr] or
							(ee.lexpr == :frameptr and ee.op == :+ and ee.rexpr.kind_of? ::Integer))
						dasm.address_binding[blockstart][:ebp] = ee
					else
						ebp_frame = false	# func does not use ebp as frame ptr, no need to bt for later blocks
					end
				end
			end

			yield block
		}

	ensure
		patched_binding.each { |a| dasm.address_binding.delete a }
		dasm.address_binding[funcstart] = oldfuncbd if oldfuncbd
	end

	# list variable dependency for each block, remove useless writes
	# returns { blockaddr => [list of vars that are needed by a following block] }
	def decompile_func_finddeps(dcmp, blocks, func)
		deps_r = {} ; deps_w = {} ; deps_to = {}
		deps_subfunc = {} 	# things read/written by subfuncs

		# find read/writes by each block
		blocks.each { |b, to|
			deps_r[b] = [] ; deps_w[b] = [] ; deps_to[b] = to
			deps_subfunc[b] = []

			blk = dcmp.dasm.decoded[b].block
			blk.list.each { |di|
				a = di.backtrace_binding.values
				w = []
				di.backtrace_binding.keys.each { |k|
					case k
					when ::Symbol; w |= [k]
					else a |= Expression[k].externals	# if dword [eax] <- 42, eax is read
					end
				}
				a << :eax if di.opcode.name == 'ret' and (not func.type.kind_of? C::BaseType or func.type.type.name != :void)	# standard ABI
				
				deps_r[b] |= a.map { |ee| Expression[ee].externals.grep(::Symbol) }.flatten - [:unknown] - deps_w[b]
				deps_w[b] |= w.map { |ee| Expression[ee].externals.grep(::Symbol) }.flatten - [:unknown]
			}
			stackoff = nil
			blk.each_to_normal { |t|
				t = dcmp.backtrace_target(t, blk.list.last.address)
				next if not t = dcmp.c_parser.toplevel.symbol[t]
				t.type = C::Function.new(C::BaseType.new(:int)) if not t.type.kind_of? C::Function	# XXX this may seem a bit extreme, and yes, it is.
				stackoff ||= Expression[dcmp.dasm.backtrace(:esp, blk.list.last.address, :snapshot_addr => blocks.first[0]).first, :-, :esp].reduce

				# things that are needed by the subfunction
				if t.has_attribute('fastcall')
					a = t.type.args.to_a
					dep = [:ecx, :edx]
					dep.shift if not a[0] or a[0].has_attribute('unused')
					dep.pop   if not a[1] or a[1].has_attribute('unused')
					deps_subfunc[b] |= dep
				end
				t.type.args.to_a.each { |arg|
					if reg = arg.has_attribute('register')
						deps_subfunc[b] |= [reg.to_sym]
					end
				}
			}
			if stackoff	# last block instr == subfunction call
				deps_r[b] |= deps_subfunc[b] - deps_w[b]
				deps_w[b] |= [:eax, :ecx, :edx]			# standard ABI
			end
		}


		bt = blocks.transpose
		roots = bt[0] - bt[1].flatten	# XXX jmp 1stblock ?

		# find regs read and never written (must have been set by caller and are part of the func ABI)
		uninitialized = lambda { |b, r, done|
			if not deps_r[b]
			elsif deps_r[b].include?(r)
				blk = dcmp.dasm.decoded[b].block
				bw = []
				rdi = blk.list.find { |di|
					a = di.backtrace_binding.values
					w = []
					di.backtrace_binding.keys.each { |k|
						case k
						when ::Symbol; w |= [k]
						else a |= Expression[k].externals	# if dword [eax] <- 42, eax is read
						end
					}
					a << :eax if di.opcode.name == 'ret' and (not func.type.kind_of? C::BaseType or func.type.type.name != :void)	# standard ABI
					
					next true if (a.map { |ee| Expression[ee].externals.grep(::Symbol) }.flatten - [:unknown] - bw).include? r
					bw |= w.map { |ee| Expression[ee].externals.grep(::Symbol) }.flatten - [:unknown]
					false
				}
				if r == :eax and (rdi || blk.list.last).opcode.name == 'ret'
					func.type.type = C::BaseType.new(:void)
					false
				elsif rdi and rdi.backtrace_binding[r]
					false	# mov al, 42 ; ret  -> don't regarg eax
				else
					true
				end
			elsif deps_w[b].include?(r)
			else
				done << b
				(deps_to[b] - done).find { |tb| uninitialized[tb, r, done] }
			end
		}

		regargs = []
		register_symbols.each { |r|
			if roots.find { |root| uninitialized[root, r, []] }
				regargs << r
			end
		}

		# TODO honor user-defined prototype if available (eg no, really, eax is not read in this function returning al)
		regargs.sort_by { |r| r.to_s }.each { |r|
			a = C::Variable.new(r.to_s, C::BaseType.new(:int, :unsigned))
			a.add_attribute("register(#{r})")
			func.type.args << a
		}

		# remove writes from a block if no following block read the value
		dw = {}
		deps_w.each { |b, deps|
			dw[b] = deps.reject { |dep|
				ret = true
				done = []
				todo = deps_to[b].dup
				while a = todo.pop
					next if done.include? a
					done << a
					if not deps_r[a] or deps_r[a].include? dep
						ret = false
						break
					elsif not deps_w[a].include? dep
						todo.concat deps_to[a]
					end
				end
				ret
			}
		}

		dw
	end

	def decompile_blocks(dcmp, myblocks, deps, func, nextaddr = nil)
		scope = func.initializer
		func.type.args.each { |a| scope.symbol[a.name] = a }
		stmts = scope.statements
		blocks_toclean = myblocks.dup
		func_entry = myblocks.first[0]
		until myblocks.empty?
			b, to = myblocks.shift
			if l = dcmp.dasm.get_label_at(b)
				stmts << C::Label.new(l)
			end

			# list of assignments [[dest reg, expr assigned]]
			ops = []
			# reg binding (reg => value, values.externals = regs at block start)
			binding = {}
			# Expr => CExpr
			ce  = lambda { |*e| dcmp.decompile_cexpr(Expression[Expression[*e].reduce], scope) }
			# Expr => Expr.bind(binding) => CExpr
			ceb = lambda { |*e| ce[Expression[*e].bind(binding)] }

			# dumps a CExprs that implements an assignment to a reg (uses ops[], patches op => [reg, nil])
			commit = lambda {
				deps[b].map { |k|
					[k, ops.rindex(ops.reverse.find { |r, v| r == k })]
				}.sort_by { |k, i| i.to_i }.each { |k, i|
					next if not i or not binding[k]
					e = k
					final = []
					ops[0..i].reverse_each { |r, v|
						final << r if not v
						e = Expression[e].bind(r => v).reduce if not final.include? r
					}
					ops[i][1] = nil
					binding.delete k
					stmts << ce[k, :'=', e] if k != e
				}
			}

			# returns an array to use as funcall arguments
			get_func_args = lambda { |di, f|
				# XXX see remarks in #finddeps
				bt = dcmp.dasm.backtrace(:esp, di.address, :snapshot_addr => func_entry, :include_start => true)
				stackoff = Expression[[bt, :+, @size/8], :-, :esp].bind(:esp => :frameptr).reduce rescue nil
				args_todo = f.type.args.to_a.dup
				args = []
				if f.has_attribute('fastcall')	# XXX DRY
					if a = args_todo.shift
						mask = (1 << (8*dcmp.c_parser.sizeof(a))) - 1
						mask = 0 if a.has_attribute('unused')
						args << Expression[:ecx, :&, mask]
					end
					if a = args_todo.shift
						mask = (1 << (8*dcmp.c_parser.sizeof(a))) - 1	# char => dl
						mask = 0 if a.has_attribute('unused')
						args << Expression[:edx, :&, mask]
					end
				end
				args_todo.each { |a_|
					if r = a_.has_attribute_var('register')
						args << Expression[r.to_sym]
					elsif stackoff.kind_of? Integer
						args << Indirection[[:frameptr, :+, stackoff], @size/8]
						stackoff += [dcmp.sizeof(a_), @size/8].max
					else
						args << Expression[0]
					end
				}

				if f.type.varargs and f.type.args.last.type.pointer? and stackoff.kind_of? Integer
					# check if last arg is a fmtstring
					bt = dcmp.dasm.backtrace(args.last, di.address, :snapshot_addr => func_entry, :include_start => true)
					if bt.length == 1 and s = dcmp.dasm.get_section_at(bt.first)
						fmt = s[0].read(512)
						fmt = fmt.unpack('v*').pack('C*') if dcmp.sizeof(f.type.args.last.type.untypedef.type) == 2
						if fmt.index(?\0)
							fmt = fmt[0...fmt.index(?\0)]
							fmt.gsub('%%', '').count('%').times {	# XXX %.*s etc..
								args << Indirection[[:frameptr, :+, stackoff], @size/8]
								stackoff += @size/8
							}
						end
					end
				end

				args.map { |e| ceb[e] }
			}

			# go !
			dcmp.dasm.decoded[b].block.list.each_with_index { |di, didx|
				a = di.instruction.args
				if di.opcode.props[:setip] and not di.opcode.props[:stopexec]
					# conditional jump
					commit[]
					n = dcmp.backtrace_target(get_xrefs_x(dcmp.dasm, di).first, di.address)
					if di.opcode.name =~ /^loop(.+)?/
						cx = C::CExpression[:'--', ceb[:ecx]]
						cc = $1 ? C::CExpression[cx, :'&&', ceb[decode_cc_to_expr($1)]] : cx
					else
						cc = ceb[decode_cc_to_expr(di.opcode.name[1..-1])]
					end
					# XXX switch/indirect/multiple jmp
					stmts << C::If.new(C::CExpression[cc], C::Goto.new(n))
					to.delete dcmp.dasm.normalize(n)
					next
				end

				if di.opcode.name == 'mov'
					# mov cr0 etc
					a1, a2 = di.instruction.args
					case a1
					when Ia32::CtrlReg, Ia32::DbgReg, Ia32::TstReg, Ia32::SegReg
						sz = a1.kind_of?(Ia32::SegReg) ? 16 : 32
						if not dcmp.c_parser.toplevel.symbol["intrinsic_set_#{a1}"]
							dcmp.c_parser.parse("void intrinsic_set_#{a1}(__int#{sz});")
						end
						f = dcmp.c_parser.toplevel.symbol["intrinsic_set_#{a1}"]
						a2 = a2.symbolic(di)
						a2 = [a2, :&, 0xffff] if sz == 16
						stmts << C::CExpression.new(f, :funcall, [ceb[a2]], f.type.type)
						next
					end
					case a2
					when Ia32::CtrlReg, Ia32::DbgReg, Ia32::TstReg, Ia32::SegReg
						if not dcmp.c_parser.toplevel.symbol["intrinsic_get_#{a2}"]
							sz = a2.kind_of?(Ia32::SegReg) ? 16 : 32
							dcmp.c_parser.parse("__int#{sz} intrinsic_get_#{a2}(void);")
						end
						f = dcmp.c_parser.toplevel.symbol["intrinsic_get_#{a2}"]
						t = f.type.type
						binding.delete a1.symbolic(di)
						stmts << C::CExpression.new(ce[a1.symbolic(di)], :'=', C::CExpression.new(f, :funcall, [], t), t)
						next
					end
				end

				case di.opcode.name
				when 'ret'
					commit[]
					ret = nil
					ret = C::CExpression[ceb[:eax]] unless func.type.type.kind_of? C::BaseType and func.type.type.name == :void
					stmts << C::Return.new(ret)
				when 'call'	# :saveip
					n = dcmp.backtrace_target(get_xrefs_x(dcmp.dasm, di).first, di.address)
					args = []
					if f = dcmp.c_parser.toplevel.symbol[n] and f.type.kind_of? C::Function and f.type.args
						args = get_func_args[di, f]
					elsif defined? @dasm_func_default_off and o = @dasm_func_default_off[[dcmp.dasm, di.address]] and o.kind_of? Integer and o > @size/8
						f = C::Variable.new
						f.type = C::Function.new(C::BaseType.new(:int), [])
						((o/(@size/8))-1).times { f.type.args << C::Variable.new(nil,C::BaseType.new(:int)) }
						args = get_func_args[di, f]
					end
					commit[]
					#next if not di.block.to_subfuncret

					if not n.kind_of? ::String or (f and not f.type.kind_of? C::Function)
						# indirect funcall
						fptr = ceb[n]
						binding.delete n
						proto = C::Function.new(C::BaseType.new(:int))
						proto = f.type if f and f.type.kind_of? C::Function
						f = C::CExpression[[fptr], C::Pointer.new(proto)]
					elsif not f
						# internal functions are predeclared, so this one is extern
						f = C::Variable.new
						f.name = n
						f.type = C::Function.new(C::BaseType.new(:int))
						if dcmp.recurse > 0
							dcmp.c_parser.toplevel.symbol[n] = f
							dcmp.c_parser.toplevel.statements << C::Declaration.new(f)
						end
					end
					commit[]
					binding.delete :eax
					e = C::CExpression[f, :funcall, args]
					e = C::CExpression[ce[:eax], :'=', e, f.type.type] if deps[b].include? :eax and f.type.type != C::BaseType.new(:void)
					stmts << e
				when 'jmp'
					#if di.comment.to_a.include? 'switch'
					#	n = di.instruction.args.first.symbolic(di)
					#	fptr = ceb[n]
					#	binding.delete n
					#	commit[]
					#	sw = C::Switch.new(fptr, C::Block.new(scope))
					#	di.block.to_normal.to_a.each { |addr|
					#		addr = dcmp.dasm.normalize addr
					#		to.delete addr
					#		next if not l = dcmp.dasm.get_label_at(addr)
					#		sw.body.statements << C::Goto.new(l)
 					#	}
					#	stmts << sw
					a = di.instruction.args.first
					if a.kind_of? Expression
					elsif not a.respond_to? :symbolic
						stmts << C::Asm.new(di.instruction.to_s, nil, [], [], nil, nil)
					else
						n = di.instruction.args.first.symbolic(di)
						fptr = ceb[n]
						binding.delete n
						commit[]
						if fptr.kind_of? C::CExpression and fptr.type.pointer? and fptr.type.untypedef.type.kind_of? C::Function
							proto = fptr.type.untypedef.type
							args = get_func_args[di, fptr.type]
						else
							proto = C::Function.new(C::BaseType.new(:void))
							fptr = C::CExpression[[fptr], C::Pointer.new(proto)]
							args = []
						end
						ret = C::Return.new(C::CExpression[fptr, :funcall, args])
						class << ret ; attr_accessor :from_instr end
						ret.from_instr = di
						stmts << ret
						to = []
					end
				when 'lgdt'
					if not dcmp.c_parser.toplevel.struct['segment_descriptor']
						dcmp.c_parser.parse('struct segment_descriptor { __int16 limit; __int16 base0_16; __int8 base16_24; __int8 flags1; __int8 flags2_limit_16_20; __int8 base24_32; };')
						dcmp.c_parser.parse('struct segment_table { __int16 size; struct segment_descriptor *table; } __attribute__((pack(2)));')
					end
					if not dcmp.c_parser.toplevel.symbol['intrinsic_lgdt']
						dcmp.c_parser.parse('void intrinsic_lgdt(struct segment_table *);')
					end
					# need a way to transform arg => :frameptr+12
					arg = di.backtrace_binding.keys.grep(Indirection).first.pointer
					stmts << C::CExpression.new(dcmp.c_parser.toplevel.symbol['intrinsic_lgdt'], :funcall, [ceb[arg]], C::BaseType.new(:void))
				when 'lidt'
					if not dcmp.c_parser.toplevel.struct['interrupt_descriptor']
						dcmp.c_parser.parse('struct interrupt_descriptor { __int16 offset0_16; __int16 segment; __int16 flags; __int16 offset16_32; };')
						dcmp.c_parser.parse('struct interrupt_table { __int16 size; struct interrupt_descriptor *table; } __attribute__((pack(2)));')
					end
					if not dcmp.c_parser.toplevel.symbol['intrinsic_lidt']
						dcmp.c_parser.parse('void intrinsic_lidt(struct interrupt_table *);')
					end
					arg = di.backtrace_binding.keys.grep(Indirection).first.pointer
					stmts << C::CExpression.new(dcmp.c_parser.toplevel.symbol['intrinsic_lidt'], :funcall, [ceb[arg]], C::BaseType.new(:void))
				when 'ltr', 'lldt'
					if not dcmp.c_parser.toplevel.symbol["intrinsic_#{di.opcode.name}"]
						dcmp.c_parser.parse("void intrinsic_#{di.opcode.name}(int);")
					end
					arg = di.backtrace_binding.keys.first
					stmts << C::CExpression.new(dcmp.c_parser.toplevel.symbol["intrinsic_#{di.opcode.name}"], :funcall, [ceb[arg]], C::BaseType.new(:void))
				when 'out'
					sz = di.instruction.args.find { |a_| a_.kind_of? Ia32::Reg and a_.val == 0 }.sz
					if not dcmp.c_parser.toplevel.symbol["intrinsic_out#{sz}"]
						dcmp.c_parser.parse("void intrinsic_out#{sz}(unsigned short port, __int#{sz} value);")
					end
					port = di.instruction.args.grep(Expression).first || :edx
					stmts << C::CExpression.new(dcmp.c_parser.toplevel.symbol["intrinsic_out#{sz}"], :funcall, [ceb[port], ceb[:eax]], C::BaseType.new(:void))
				when 'in'
					sz = di.instruction.args.find { |a_| a_.kind_of? Ia32::Reg and a_.val == 0 }.sz
					if not dcmp.c_parser.toplevel.symbol["intrinsic_in#{sz}"]
						dcmp.c_parser.parse("__int#{sz} intrinsic_in#{sz}(unsigned short port);")
					end
					port = di.instruction.args.grep(Expression).first || :edx
					f = dcmp.c_parser.toplevel.symbol["intrinsic_in#{sz}"]
					binding.delete :eax
					stmts << C::CExpression.new(ce[:eax], :'=', C::CExpression.new(f, :funcall, [ceb[port]], f.type.type), f.type.type)
				when 'sti', 'cli'
					stmts << C::Asm.new(di.instruction.to_s, nil, [], [], nil, nil)
				when /^(mov|sto|lod)s([bwdq])/
					op, sz = $1, $2
					commit[]
					sz = { 'b' => 1, 'w' => 2, 'd' => 4, 'q' => 8 }[sz]
					pt = C::Pointer.new(C::BaseType.new("__int#{sz*8}".to_sym))

					blk = C::Block.new(scope)
					case op
					when 'mov'
						blk.statements << C::CExpression[[:*, [[ceb[:edi]], pt]], :'=', [:*, [[ceb[:esi]], pt]]]
						blk.statements << C::CExpression[ceb[:edi], :'=', [ceb[:edi], :+, [sz]]]
						blk.statements << C::CExpression[ceb[:esi], :'=', [ceb[:esi], :+, [sz]]]
					when 'sto'
						blk.statements << C::CExpression[[:*, [[ceb[:edi]], pt]], :'=', ceb[:eax]]
						blk.statements << C::CExpression[ceb[:edi], :'=', [ceb[:edi], :+, [sz]]]
					when 'lod'
						blk.statements << C::CExpression[ceb[:eax], :'=', [:*, [[ceb[:esi]], pt]]]
						blk.statements << C::CExpression[ceb[:esi], :'=', [ceb[:esi], :+, [sz]]]
					#when 'sca'
					#when 'cmp'
					end

					case (di.instruction.prefix || {})[:rep]
					when nil
						stmts.concat blk.statements
					when 'rep'
						blk.statements << C::CExpression[ceb[:ecx], :'=', [ceb[:ecx], :-, [1]]]
						stmts << C::While.new(C::CExpression[ceb[:ecx]], blk)
					#when 'repz'	# sca/cmp only
					#when 'repnz'
					end
					next
				else
					bd = get_fwdemu_binding(di)
					if di.backtrace_binding[:incomplete_binding]
						commit[]
						stmts << C::Asm.new(di.instruction.to_s, nil, nil, nil, nil, nil)
					else
						update = {}
						bd.each { |k, v|
							if k.kind_of? ::Symbol and not deps[b].include? k
								ops << [k, v]
								update[k] = Expression[Expression[v].bind(binding).reduce]
							else
								stmts << ceb[k, :'=', v]
								stmts.pop if stmts.last.kind_of? C::Variable	# [:eflag_s, :=, :unknown].reduce
							end
						}
						binding.update update
					end
				end
			}
			commit[]

			case to.length
			when 0
				if not myblocks.empty? and not %w[ret jmp].include? dcmp.dasm.decoded[b].block.list.last.instruction.opname
					puts "  block #{Expression[b]} has no to and don't end in ret"
				end
			when 1
				if (myblocks.empty? ? nextaddr != to[0] : myblocks.first.first != to[0])
					stmts << C::Goto.new(dcmp.dasm.auto_label_at(to[0], 'unknown_goto'))
				end
			else
				puts "  block #{Expression[b]} with multiple to"
			end
		end

		# cleanup di.bt_binding (we set :frameptr etc in those, this may confuse the dasm)
		blocks_toclean.each { |b_, to_|
			dcmp.dasm.decoded[b_].block.list.each { |di|
				di.backtrace_binding = nil
			}
	       	}
	end
	
	def decompile_check_abi(dcmp, entry, func)
		a = func.type.args || []
		a.delete_if { |arg| arg.has_attribute_var('register') and arg.has_attribute('unused') }
		ra =  a.map { |arg| arg.has_attribute_var('register') }.compact
		if (a.length == 1 and ra == ['ecx']) or (a.length >= 2 and ra.sort == ['ecx', 'edx'])
			func.add_attribute 'fastcall'
			# reorder args
			ecx = a.find { |arg| arg.has_attribute_var('register') == 'ecx' }
			edx = a.find { |arg| arg.has_attribute_var('register') == 'edx' }
			a.insert(0, a.delete(ecx))
			a.insert(1, a.delete(edx)) if edx
		end

		if not f = dcmp.dasm.function[entry] or not f.return_address
			#func.add_attribute 'noreturn'
		else
			adj = f.return_address.map { |ra_| dcmp.dasm.backtrace(:esp, ra_, :include_start => true, :stopaddr => entry) }.flatten.uniq
			if adj.length == 1 and so = Expression[adj.first, :-, :esp].reduce and so.kind_of? ::Integer
				argsz = a.map { |fa|
					next if not fa.stackoff
					(fa.stackoff + [dcmp.sizeof(fa), dcmp.c_parser.typesize[:ptr]].max-1) / dcmp.c_parser.typesize[:ptr]
				}.compact.max.to_i
				so /= dcmp.dasm.cpu.size/8
				so -= 1
				if so > argsz
					aso = a.empty? ? 0 : a.last.stackoff.to_i + dcmp.c_parser.typesize[:ptr]
					(so-argsz).times {
						a << C::Variable.new(dcmp.stackoff_to_varname(aso), C::BaseType.new(:int))
						a.last.add_attribute('unused')
						aso += dcmp.sizeof(a.last)
					}
					argsz = so
				end
				case so
				when 0
				when argsz
					func.add_attribute 'stdcall' if not func.has_attribute('fastcall')
				else
					func.add_attribute "stackoff:#{so*dcmp.dasm.cpu.size/8}"
				end
			else
				func.add_attribute "breakstack:#{adj.inspect}"
			end
		end
	end
end
end
